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cam 2017-04-19 20:27:49 +10:00
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ifndef MAKEFILE_INCLUDED
include ../../Makefile
endif

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/*
Copyright 2012 Jun Wako <wakojun@gmail.com>
This program is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 2 of the License, or
(at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program. If not, see <http://www.gnu.org/licenses/>.
*/
#ifndef CONFIG_H
#define CONFIG_H
#include "config_common.h"
/* USB Device descriptor parameter */
#define VENDOR_ID 0xFEED
#define PRODUCT_ID 0x6060
#define DEVICE_VER 0x0001
#define MANUFACTURER unknown
#define PRODUCT Mitosis
#define DESCRIPTION q.m.k. keyboard firmware for Mitosis
/* key matrix size */
#define MATRIX_ROWS 5
#define MATRIX_COLS 10
/* define if matrix has ghost */
//#define MATRIX_HAS_GHOST
/* number of backlight levels */
//#define BACKLIGHT_LEVELS 3
#define ONESHOT_TIMEOUT 500
/* key combination for command */
#define IS_COMMAND() ( \
keyboard_report->mods == (MOD_BIT(KC_LSHIFT) | MOD_BIT(KC_RSHIFT)) \
)
/*
* Feature disable options
* These options are also useful to firmware size reduction.
*/
#define PREVENT_STUCK_MODIFIERS
/* disable debug print */
//#define NO_DEBUG
/* disable print */
//#define NO_PRINT
/* disable action features */
//#define NO_ACTION_LAYER
//#define NO_ACTION_TAPPING
//#define NO_ACTION_ONESHOT
//#define NO_ACTION_MACRO
//#define NO_ACTION_FUNCTION
//UART settings for communication with the RF microcontroller
#define SERIAL_UART_BAUD 1000000
#define SERIAL_UART_DATA UDR1
#define SERIAL_UART_UBRR (F_CPU / (16UL * SERIAL_UART_BAUD) - 1)
#define SERIAL_UART_TXD_READY (UCSR1A & _BV(UDRE1))
#define SERIAL_UART_RXD_PRESENT (UCSR1A & _BV(RXC1))
#define SERIAL_UART_INIT() do { \
/* baud rate */ \
UBRR1L = SERIAL_UART_UBRR; \
/* baud rate */ \
UBRR1H = SERIAL_UART_UBRR >> 8; \
/* enable TX and RX */ \
UCSR1B = _BV(TXEN1) | _BV(RXEN1); \
/* 8-bit data */ \
UCSR1C = _BV(UCSZ11) | _BV(UCSZ10); \
} while(0)
#endif

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// this is the style you want to emulate.
// This is the canonical layout file for the Quantum project. If you want to add another keyboard,
#include "mitosis.h"
// Each layer gets a name for readability, which is then used in the keymap matrix below.
// The underscores don't mean anything - you can have a layer called STUFF or any other name.
// Layer names don't all need to be of the same length, obviously, and you can also skip them
// entirely and just use numbers.
enum mitosis_layers
{
_MALT,
_SHIFTED,
_FUNCTION,
_FUNCSHIFT
};
enum mitosis_keycodes
{
FNKEY = SAFE_RANGE,
SHIFT
};
// Macro definitions for readability
enum mitosis_macros
{
VOLU,
VOLD,
ESCM
};
#define LONGPRESS_DELAY 150
#define LAYER_TOGGLE_DELAY 300
// Fillers to make layering more clear
#define _______ KC_TRNS
#define XXXXXXX KC_NO
const uint16_t PROGMEM keymaps[][MATRIX_ROWS][MATRIX_COLS] = {
[_MALT] = { /* Malt Layout, customised for reduced columns (ex: quote and shift locations) */
{KC_Q, KC_P, KC_Y, KC_C, KC_B, KC_V, KC_M, KC_U, KC_Z, KC_L },
{KC_A, KC_N, KC_I, KC_S, KC_F, KC_D, KC_T, KC_H, KC_O, KC_R },
{KC_COMM, KC_DOT, KC_J, KC_G, KC_SLSH, KC_SCLN, KC_W, KC_K, KC_QUOT, KC_X },
{XXXXXXX, M(VOLU), M(ESCM), KC_TAB, KC_LCTL, KC_LALT, KC_ENT, KC_DEL, KC_PGUP, XXXXXXX },
{XXXXXXX, M(VOLD), KC_LGUI, KC_E, FNKEY, SHIFT, KC_SPC, KC_BSPC, KC_PGDN, XXXXXXX }
},
[_SHIFTED] = { /* Shifted Layer, layered so that tri_layer can be used, or selectively
able to modify individual key's shifted behaviour */
{_______, _______, _______, _______, _______, _______, _______, _______, _______, _______ },
{_______, _______, _______, _______, _______, _______, _______, _______, _______, _______ },
{_______, _______, _______, _______, _______, _______, _______, _______, _______, _______ },
{XXXXXXX, _______, _______, _______, _______, _______, _______, _______, _______, XXXXXXX },
{XXXXXXX, _______, _______, _______, _______, _______, _______, _______, _______, XXXXXXX }
},
[_FUNCTION] = { /* Function Layer, primary alternative layer featuring numpad on right hand,
cursor keys on left hand, and all symbols*/
{KC_AMPR, KC_PERC, KC_UP, KC_CIRC, KC_PIPE, KC_LBRC, KC_7, KC_8, KC_9, KC_MINS },
{KC_AT, KC_LEFT, KC_DOWN, KC_RGHT, KC_HASH, KC_LPRN, KC_4, KC_5, KC_6, KC_PLUS },
{KC_ASTR, KC_UNDS, KC_EXLM, KC_DLR, KC_BSLS, KC_LCBR, KC_1, KC_2, KC_3, KC_ENT },
{XXXXXXX, KC_HOME, KC_GRV, KC_PWR, _______, _______, KC_EQL, KC_TILD, KC_DOT, XXXXXXX },
{XXXXXXX, KC_END, _______, _______, _______, _______, KC_0, _______, KC_PSCR, XXXXXXX }
},
[_FUNCSHIFT] = { /* Function Shifted Layer, secondary alternative layer with closing brackets,
and F-keys under their numpad equivalents*/
{_______, _______, _______, _______, _______, KC_RBRC, KC_F7, KC_F8, KC_F9, KC_F10 },
{_______, _______, _______, _______, _______, KC_RPRN, KC_F4, KC_F5, KC_F6, KC_F11 },
{_______, _______, _______, _______, _______, KC_RCBR, KC_F1, KC_F2, KC_F3, KC_F12 },
{XXXXXXX, _______, _______, _______, _______, _______, _______, _______, _______, XXXXXXX },
{XXXXXXX, _______, _______, _______, _______, _______, _______, _______, _______, XXXXXXX }
}
};
const uint16_t PROGMEM fn_actions[] = {
};
static uint16_t key_timer;
const macro_t *action_get_macro(keyrecord_t *record, uint8_t id, uint8_t opt)
{
// MACRODOWN only works in this function
switch(id) {
//switch multiplexing for media, short tap for volume up, long press for play/pause
case VOLU:
if (record->event.pressed) {
key_timer = timer_read(); // if the key is being pressed, we start the timer.
} else { // this means the key was just released, so we can figure out how long it was pressed for (tap or "held down").
if (timer_elapsed(key_timer) > LONGPRESS_DELAY) { // LONGPRESS_DELAY being 150ms, the threshhold we pick for counting something as a tap.
return MACRO(T(MPLY), END);
} else {
return MACRO(T(VOLU), END);
}
}
break;
//switch multiplexing for media, short tap for volume down, long press for next track
case VOLD:
if (record->event.pressed) {
key_timer = timer_read();
} else {
if (timer_elapsed(key_timer) > LONGPRESS_DELAY) {
return MACRO(T(MNXT), END);
} else {
return MACRO(T(VOLD), END);
}
}
break;
//switch multiplexing for escape, short tap for escape, long press for context menu
case ESCM:
if (record->event.pressed) {
key_timer = timer_read();
} else {
if (timer_elapsed(key_timer) > LONGPRESS_DELAY) {
return MACRO(T(APP), END);
} else {
return MACRO(T(ESC), END);
}
}
break;
break;
}
return MACRO_NONE;
};
static bool singular_key = false;
bool process_record_user(uint16_t keycode, keyrecord_t *record) {
uint8_t layer;
layer = biton32(layer_state); // get the current layer
//custom layer handling for tri_layer,
switch (keycode) {
case FNKEY:
if (record->event.pressed) {
key_timer = timer_read();
singular_key = true;
layer_on(_FUNCTION);
} else {
if (timer_elapsed(key_timer) < LAYER_TOGGLE_DELAY || !singular_key) {
layer_off(_FUNCTION);
}
}
update_tri_layer(_FUNCTION, _SHIFTED, _FUNCSHIFT);
return false;
break;
//SHIFT is handled as LSHIFT in the general case
case SHIFT:
if (record->event.pressed) {
key_timer = timer_read();
singular_key = true;
layer_on(_SHIFTED);
register_code(KC_LSFT);
} else {
if (timer_elapsed(key_timer) < LAYER_TOGGLE_DELAY || !singular_key) {
layer_off(_SHIFTED);
unregister_code(KC_LSFT);
}
}
update_tri_layer(_FUNCTION, _SHIFTED, _FUNCSHIFT);
return false;
break;
//If any other key was pressed during the layer mod hold period,
//then the layer mod was used momentarily, and should block latching
default:
singular_key = false;
break;
}
//FUNCSHIFT has been shifted by the SHIFT handling, some keys need to be excluded
if (layer == _FUNCSHIFT) {
//F1-F12 should be sent as unshifted keycodes,
//and ] needs to be unshifted or it is sent as }
if ( (keycode >= KC_F1 && keycode <= KC_F12)
|| keycode == KC_RBRC ) {
if (record->event.pressed) {
unregister_mods(MOD_LSFT);
} else {
register_mods(MOD_LSFT);
}
}
}
return true;
};
void matrix_scan_user(void) {
uint8_t layer = biton32(layer_state);
switch (layer) {
case _MALT:
set_led_off;
break;
case _FUNCTION:
set_led_blue;
break;
case _SHIFTED:
set_led_red;
break;
case _FUNCSHIFT:
set_led_green;
break;
default:
break;
}
};

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/*
Copyright 2012 Jun Wako
Copyright 2014 Jack Humbert
This program is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 2 of the License, or
(at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with this program. If not, see <http://www.gnu.org/licenses/>.
*/
#include <stdint.h>
#include <stdbool.h>
#if defined(__AVR__)
#include <avr/io.h>
#endif
#include "wait.h"
#include "print.h"
#include "debug.h"
#include "util.h"
#include "matrix.h"
#include "timer.h"
#if (MATRIX_COLS <= 8)
# define print_matrix_header() print("\nr/c 01234567\n")
# define print_matrix_row(row) print_bin_reverse8(matrix_get_row(row))
# define matrix_bitpop(i) bitpop(matrix[i])
# define ROW_SHIFTER ((uint8_t)1)
#elif (MATRIX_COLS <= 16)
# define print_matrix_header() print("\nr/c 0123456789ABCDEF\n")
# define print_matrix_row(row) print_bin_reverse16(matrix_get_row(row))
# define matrix_bitpop(i) bitpop16(matrix[i])
# define ROW_SHIFTER ((uint16_t)1)
#elif (MATRIX_COLS <= 32)
# define print_matrix_header() print("\nr/c 0123456789ABCDEF0123456789ABCDEF\n")
# define print_matrix_row(row) print_bin_reverse32(matrix_get_row(row))
# define matrix_bitpop(i) bitpop32(matrix[i])
# define ROW_SHIFTER ((uint32_t)1)
#endif
/* matrix state(1:on, 0:off) */
static matrix_row_t matrix[MATRIX_ROWS];
__attribute__ ((weak))
void matrix_init_quantum(void) {
matrix_init_kb();
}
__attribute__ ((weak))
void matrix_scan_quantum(void) {
matrix_scan_kb();
}
__attribute__ ((weak))
void matrix_init_kb(void) {
matrix_init_user();
}
__attribute__ ((weak))
void matrix_scan_kb(void) {
matrix_scan_user();
}
__attribute__ ((weak))
void matrix_init_user(void) {
}
__attribute__ ((weak))
void matrix_scan_user(void) {
}
inline
uint8_t matrix_rows(void) {
return MATRIX_ROWS;
}
inline
uint8_t matrix_cols(void) {
return MATRIX_COLS;
}
void matrix_init(void) {
matrix_init_quantum();
}
uint8_t matrix_scan(void)
{
SERIAL_UART_INIT();
uint32_t timeout = 0;
//the s character requests the RF slave to send the matrix
SERIAL_UART_DATA = 's';
//trust the external keystates entirely, erase the last data
uint8_t uart_data[11] = {0};
//there are 10 bytes corresponding to 10 columns, and an end byte
for (uint8_t i = 0; i < 11; i++) {
//wait for the serial data, timeout if it's been too long
//this only happened in testing with a loose wire, but does no
//harm to leave it in here
while(!SERIAL_UART_RXD_PRESENT){
timeout++;
if (timeout > 10000){
break;
}
}
uart_data[i] = SERIAL_UART_DATA;
}
//check for the end packet, the key state bytes use the LSBs, so 0xE0
//will only show up here if the correct bytes were recieved
if (uart_data[10] == 0xE0)
{
//shifting and transferring the keystates to the QMK matrix variable
for (uint8_t i = 0; i < MATRIX_ROWS; i++) {
matrix[i] = (uint16_t) uart_data[i*2] | (uint16_t) uart_data[i*2+1] << 5;
}
}
matrix_scan_quantum();
return 1;
}
inline
bool matrix_is_on(uint8_t row, uint8_t col)
{
return (matrix[row] & ((matrix_row_t)1<col));
}
inline
matrix_row_t matrix_get_row(uint8_t row)
{
return matrix[row];
}
void matrix_print(void)
{
print_matrix_header();
for (uint8_t row = 0; row < MATRIX_ROWS; row++) {
phex(row); print(": ");
print_matrix_row(row);
print("\n");
}
}
uint8_t matrix_key_count(void)
{
uint8_t count = 0;
for (uint8_t i = 0; i < MATRIX_ROWS; i++) {
count += matrix_bitpop(i);
}
return count;
}

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#include "mitosis.h"
void uart_init(void) {
SERIAL_UART_INIT();
}
void led_init(void) {
DDRD |= (1<<1);
PORTD |= (1<<1);
DDRF |= (1<<4) | (1<<5);
PORTF |= (1<<4) | (1<<5);
}
void matrix_init_kb(void) {
// put your keyboard start-up code here
// runs once when the firmware starts up
matrix_init_user();
uart_init();
led_init();
}
void matrix_scan_kb(void) {
// put your looping keyboard code here
// runs every cycle (a lot)
matrix_scan_user();
}
void led_set_kb(uint8_t usb_led) {
}

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#ifndef MITOSIS_H
#define MITOSIS_H
#include "quantum.h"
#include "matrix.h"
#include "backlight.h"
#include <stddef.h>
#define red_led_off PORTF |= (1<<5)
#define red_led_on PORTF &= ~(1<<5)
#define blu_led_off PORTF |= (1<<4)
#define blu_led_on PORTF &= ~(1<<4)
#define grn_led_off PORTD |= (1<<1)
#define grn_led_on PORTD &= ~(1<<1)
#define set_led_off red_led_off; grn_led_off; blu_led_off
#define set_led_red red_led_on; grn_led_off; blu_led_off
#define set_led_blue red_led_off; grn_led_off; blu_led_on
#define set_led_green red_led_off; grn_led_on; blu_led_off
#define set_led_yellow red_led_on; grn_led_on; blu_led_off
#define set_led_magenta red_led_on; grn_led_off; blu_led_on
#define set_led_cyan red_led_off; grn_led_on; blu_led_on
#define set_led_white red_led_on; grn_led_on; blu_led_on
/*
#define LED_B 5
#define LED_R 6
#define LED_G 7
#define all_leds_off PORTF &= ~(1<<LED_B) & ~(1<<LED_R) & ~(1<<LED_G)
#define red_led_on PORTF |= (1<<LED_R)
#define red_led_off PORTF &= ~(1<<LED_R)
#define grn_led_on PORTF |= (1<<LED_G)
#define grn_led_off PORTF &= ~(1<<LED_G)
#define blu_led_on PORTF |= (1<<LED_B)
#define blu_led_off PORTF &= ~(1<<LED_B)
#define set_led_off PORTF &= ~(1<<LED_B) & ~(1<<LED_R) & ~(1<<LED_G)
#define set_led_red PORTF = PORTF & ~(1<<LED_B) & ~(1<<LED_G) | (1<<LED_R)
#define set_led_blue PORTF = PORTF & ~(1<<LED_G) & ~(1<<LED_R) | (1<<LED_B)
#define set_led_green PORTF = PORTF & ~(1<<LED_B) & ~(1<<LED_R) | (1<<LED_G)
#define set_led_yellow PORTF = PORTF & ~(1<<LED_B) | (1<<LED_R) | (1<<LED_G)
#define set_led_magenta PORTF = PORTF & ~(1<<LED_G) | (1<<LED_R) | (1<<LED_B)
#define set_led_cyan PORTF = PORTF & ~(1<<LED_R) | (1<<LED_B) | (1<<LED_G)
#define set_led_white PORTF |= (1<<LED_B) | (1<<LED_R) | (1<<LED_G)
*/
// This a shortcut to help you visually see your layout.
// The first section contains all of the arguements
// The second converts the arguments into a two-dimensional array
#define KEYMAP( \
k00, k01, k02, k03, k04, k05, k06, k07, k08, k09, \
k10, k11, k12, k13, k14, k15, k16, k17, k18, k19, \
k20, k21, k22, k23, k24, k25, k26, k27, k28, k29, \
k31, k32, k33, k34, k35, k36, k37, k38, \
k41, k42, k43, k44, k45, k46, k47, k48 \
) \
{ \
{ k00, k01, k02, k03, k04, k05, k06, k07, k08, k09 }, \
{ k10, k11, k12, k13, k14, k15, k16, k17, k18, k19 }, \
{ k20, k21, k22, k23, k24, k25, k26, k27, k28, k29 }, \
{ KC_NO, k31, k32, k33, k34, k35, k36, k37, k38, KC_NO } \
{ KC_NO, k41, k42, k43, k44, k45, k46, k47, k48, KC_NO }, \
}
#endif

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mitosis keyboard firmware
======================
## Quantum MK Firmware
You have access to a bunch of goodies! Check out the Makefile to enable/disable some of the features. Uncomment the `#` to enable them. Setting them to `no` does nothing and will only confuse future you.
BACKLIGHT_ENABLE = yes # Enable keyboard backlight functionality
MIDI_ENABLE = yes # MIDI controls
# UNICODE_ENABLE = yes # Unicode support - this is commented out, just as an example. You have to use #, not //
BLUETOOTH_ENABLE = yes # Enable Bluetooth with the Adafruit EZ-Key HID
## Mitosis specific information
These configuration files were based off the Atreus keyboard. It assumes a Pro Micro is being used, however retains the 'make upload' feature from the Atreus branch. This keyboard uses a completely different 'matrix scan' system to other keyboards, it relies on an external nRF51822 microcontroller maintaining a matrix of keystates received from the keyboard halves. The matrix.c file contains the code to poll the external microcontroller for the key matrix. As long as this file is not changed, all other QMK features are supported.
## Quick aliases to common actions
Your keymap can include shortcuts to common operations (called "function actions" in tmk).
### Switching and toggling layers
`MO(layer)` - momentary switch to *layer*. As soon as you let go of the key, the layer is deactivated and you pop back out to the previous layer. When you apply this to a key, that same key must be set as `KC_TRNS` on the destination layer. Otherwise, you won't make it back to the original layer when you release the key (and you'll get a keycode sent). You can only switch to layers *above* your current layer. If you're on layer 0 and you use `MO(1)`, that will switch to layer 1 just fine. But if you include `MO(3)` on layer 5, that won't do anything for you -- because layer 3 is lower than layer 5 on the stack.
`LT(layer, kc)` - momentary switch to *layer* when held, and *kc* when tapped. Like `MO()`, this only works upwards in the layer stack (`layer` must be higher than the current layer).
`TG(layer)` - toggles a layer on or off. As with `MO()`, you should set this key as `KC_TRNS` in the destination layer so that tapping it again actually toggles back to the original layer. Only works upwards in the layer stack.
### Fun with modifier keys
* `LSFT(kc)` - applies left Shift to *kc* (keycode) - `S(kc)` is an alias
* `RSFT(kc)` - applies right Shift to *kc*
* `LCTL(kc)` - applies left Control to *kc*
* `RCTL(kc)` - applies right Control to *kc*
* `LALT(kc)` - applies left Alt to *kc*
* `RALT(kc)` - applies right Alt to *kc*
* `LGUI(kc)` - applies left GUI (command/win) to *kc*
* `RGUI(kc)` - applies right GUI (command/win) to *kc*
You can also chain these, like this:
LALT(LCTL(KC_DEL)) -- this makes a key that sends Alt, Control, and Delete in a single keypress.
The following shortcuts automatically add `LSFT()` to keycodes to get commonly used symbols. Their long names are also available and documented in `/quantum/keymap_common.h`.
KC_TILD ~
KC_EXLM !
KC_AT @
KC_HASH #
KC_DLR $
KC_PERC %
KC_CIRC ^
KC_AMPR &
KC_ASTR *
KC_LPRN (
KC_RPRN )
KC_UNDS _
KC_PLUS +
KC_LCBR {
KC_RCBR }
KC_PIPE |
KC_COLN :
`MT(mod, kc)` - is *mod* (modifier key - MOD_LCTL, MOD_LSFT) when held, and *kc* when tapped. In other words, you can have a key that sends Esc (or the letter O or whatever) when you tap it, but works as a Control key or a Shift key when you hold it down.
These are the values you can use for the `mod` in `MT()` (right-hand modifiers are not available):
* MOD_LCTL
* MOD_LSFT
* MOD_LALT
* MOD_LGUI
These can also be combined like `MOD_LCTL | MOD_LSFT` e.g. `MT(MOD_LCTL | MOD_LSFT, KC_ESC)` which would activate Control and Shift when held, and send Escape when tapped.
We've added shortcuts to make common modifier/tap (mod-tap) mappings more compact:
* `CTL_T(kc)` - is LCTL when held and *kc* when tapped
* `SFT_T(kc)` - is LSFT when held and *kc* when tapped
* `ALT_T(kc)` - is LALT when held and *kc* when tapped
* `GUI_T(kc)` - is LGUI when held and *kc* when tapped
* `ALL_T(kc)` - is Hyper (all mods) when held and *kc* when tapped. To read more about what you can do with a Hyper key, see [this blog post by Brett Terpstra](http://brettterpstra.com/2012/12/08/a-useful-caps-lock-key/)
### Temporarily setting the default layer
`DF(layer)` - sets default layer to *layer*. The default layer is the one at the "bottom" of the layer stack - the ultimate fallback layer. This currently does not persist over power loss. When you plug the keyboard back in, layer 0 will always be the default. It is theoretically possible to work around that, but that's not what `DF` does.
### Remember: These are just aliases
These functions work the same way that their `ACTION_*` functions do - they're just quick aliases. To dig into all of the tmk ACTION_* functions, please see the [TMK documentation](https://github.com/jackhumbert/qmk_firmware/blob/master/tmk_core/doc/keymap.md#2-action).
Instead of using `FNx` when defining `ACTION_*` functions, you can use `F(x)` - the benefit here is being able to use more than 32 function actions (up to 4096), if you happen to need them.
## Macro shortcuts: Send a whole string when pressing just one key
Instead of using the `ACTION_MACRO` function, you can simply use `M(n)` to access macro *n* - *n* will get passed into the `action_get_macro` as the `id`, and you can use a switch statement to trigger it. This gets called on the keydown and keyup, so you'll need to use an if statement testing `record->event.pressed` (see keymap_default.c).
```c
const macro_t *action_get_macro(keyrecord_t *record, uint8_t id, uint8_t opt) // this is the function signature -- just copy/paste it into your keymap file as it is.
{
switch(id) {
case 0: // this would trigger when you hit a key mapped as M(0)
if (record->event.pressed) {
return MACRO( I(255), T(H), T(E), T(L), T(L), W(255), T(O), END ); // this sends the string 'hello' when the macro executes
}
break;
}
return MACRO_NONE;
};
```
A macro can include the following commands:
* I() change interval of stroke in milliseconds.
* D() press key.
* U() release key.
* T() type key(press and release).
* W() wait (milliseconds).
* END end mark.
So above you can see the stroke interval changed to 255ms between each keystroke, then a bunch of keys being typed, waits a while, then the macro ends.
Note: Using macros to have your keyboard send passwords for you is a bad idea.
### Additional keycode aliases for software-implemented layouts (Colemak, Dvorak, etc)
Everything is assuming you're in Qwerty (in software) by default, but there is built-in support for using a Colemak or Dvorak layout by including this at the top of your keymap:
#include "keymap_<layout>.h"
Where <layout> is "colemak" or "dvorak". After including this line, you will get access to:
* `CM_*` for all of the Colemak-equivalent characters
* `DV_*` for all of the Dvorak-equivalent characters
These implementations assume you're using Colemak or Dvorak on your OS, not on your keyboard - this is referred to as a software-implemented layout. If your computer is in Qwerty and your keymap is in Colemak or Dvorak, this is referred to as a firmware-implemented layout, and you won't need these features.
To give an example, if you're using software-implemented Colemak, and want to get an `F`, you would use `CM_F` - `KC_F` under these same circumstances would result in `T`.
## Additional language support
In `quantum/keymap_extras/`, you'll see various language files - these work the same way as the alternative layout ones do. Most are defined by their two letter country/language code followed by an underscore and a 4-letter abbreviation of its name. `FR_UGRV` which will result in a `ù` when using a software-implemented AZERTY layout. It's currently difficult to send such characters in just the firmware (but it's being worked on - see Unicode support).
## Unicode support
You can currently send 4 hex digits with your OS-specific modifier key (RALT for OSX with the "Unicode Hex Input" layout) - this is currently limited to supporting one OS at a time, and requires a recompile for switching. 8 digit hex codes are being worked on. The keycode function is `UC(n)`, where *n* is a 4 digit hexidecimal. Enable from the Makefile.
## Other firmware shortcut keycodes
* `RESET` - puts the MCU in DFU mode for flashing new firmware (with `make dfu`)
* `DEBUG` - the firmware into debug mode - you'll need hid_listen to see things
* `BL_ON` - turns the backlight on
* `BL_OFF` - turns the backlight off
* `BL_<n>` - sets the backlight to level *n*
* `BL_INC` - increments the backlight level by one
* `BL_DEC` - decrements the backlight level by one
* `BL_TOGG` - toggles the backlight
* `BL_STEP` - steps through the backlight levels
Enable the backlight from the Makefile.
## MIDI functionalty
This is still a WIP, but check out `quantum/keymap_midi.c` to see what's happening. Enable from the Makefile.
## Bluetooth functionality
This requires [some hardware changes](https://www.reddit.com/r/MechanicalKeyboards/comments/3psx0q/the_planck_keyboard_with_bluetooth_guide_and/?ref=search_posts), but can be enabled via the Makefile. The firmware will still output characters via USB, so be aware of this when charging via a computer. It would make sense to have a switch on the Bluefruit to turn it off at will.
## Building
Download or clone the whole firmware and navigate to the keyboards/atreus folder. Once your dev env is setup, you'll be able to type `make` to generate your .hex - you can then use `make dfu` to program your PCB once you hit the reset button.
Depending on which keymap you would like to use, you will have to compile slightly differently.
### Default
To build with the default keymap, simply run `make default`.
### Other Keymaps
Several version of keymap are available in advance but you are recommended to define your favorite layout yourself. To define your own keymap create file named `<name>.c` and see keymap document (you can find in top readme.md) and existent keymap files.
To build the firmware binary hex file with a keymap just do `make` with a keymap like this:
```
$ make [default|jack|<name>]
```
Keymaps follow the format **__\<name\>.c__** and are stored in the `keymaps` folder.

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OPT_DEFS += -DMITOSIS_PROMICRO
OPT_DEFS += -DCATERINA_BOOTLOADER
MITOSIS_UPLOAD_COMMAND = while [ ! -r $(USB) ]; do sleep 1; done; \
avrdude -p $(MCU) -c avr109 -U flash:w:$(TARGET).hex -P $(USB)
# # project specific files
SRC = matrix.c
# MCU name
#MCU = at90usb1287
MCU = atmega32u4
# Processor frequency.
# This will define a symbol, F_CPU, in all source code files equal to the
# processor frequency in Hz. You can then use this symbol in your source code to
# calculate timings. Do NOT tack on a 'UL' at the end, this will be done
# automatically to create a 32-bit value in your source code.
#
# This will be an integer division of F_USB below, as it is sourced by
# F_USB after it has run through any CPU prescalers. Note that this value
# does not *change* the processor frequency - it should merely be updated to
# reflect the processor speed set externally so that the code can use accurate
# software delays.
F_CPU = 16000000
#
# LUFA specific
#
# Target architecture (see library "Board Types" documentation).
ARCH = AVR8
# Input clock frequency.
# This will define a symbol, F_USB, in all source code files equal to the
# input clock frequency (before any prescaling is performed) in Hz. This value may
# differ from F_CPU if prescaling is used on the latter, and is required as the
# raw input clock is fed directly to the PLL sections of the AVR for high speed
# clock generation for the USB and other AVR subsections. Do NOT tack on a 'UL'
# at the end, this will be done automatically to create a 32-bit value in your
# source code.
#
# If no clock division is performed on the input clock inside the AVR (via the
# CPU clock adjust registers or the clock division fuses), this will be equal to F_CPU.
F_USB = $(F_CPU)
# Interrupt driven control endpoint task(+60)
OPT_DEFS += -DINTERRUPT_CONTROL_ENDPOINT
# Boot Section Size in *bytes*
# Teensy halfKay 512
# Teensy++ halfKay 1024
# Atmel DFU loader 4096
# LUFA bootloader 4096
# USBaspLoader 2048
OPT_DEFS += -DBOOTLOADER_SIZE=4096
# Build Options
# comment out to disable the options.
#
#BOOTMAGIC_ENABLE = yes # Virtual DIP switch configuration(+1000)
MOUSEKEY_ENABLE ?= yes # Mouse keys(+4700)
EXTRAKEY_ENABLE ?= yes # Audio control and System control(+450)
CONSOLE_ENABLE ?= yes # Console for debug(+400)
COMMAND_ENABLE ?= yes # Commands for debug and configuration
CUSTOM_MATRIX ?= yes # Remote matrix from the wireless bridge
# Do not enable SLEEP_LED_ENABLE. it uses the same timer as BACKLIGHT_ENABLE
# SLEEP_LED_ENABLE ?= yes # Breathing sleep LED during USB suspend
NKRO_ENABLE ?= yes # USB Nkey Rollover - not yet supported in LUFA
# BACKLIGHT_ENABLE ?= yes # Enable keyboard backlight functionality
# MIDI_ENABLE ?= YES # MIDI controls
UNICODE_ENABLE ?= YES # Unicode
# BLUETOOTH_ENABLE ?= yes # Enable Bluetooth with the Adafruit EZ-Key HID
USB ?= /dev/ttyACM0
upload: build
$(MITOSIS_UPLOAD_COMMAND)